Within the global realism program, spacetime vacuum is treated as the sole fundamental physical substrate, while elementary particles are interpreted as localized topological excitations of that substrate rather than as primitive point objects. The present manuscript develops a microscopic statistical-mechanical completion of that program by reconstructing a full chain from microscopic ontology to corrected kinetic description and from corrected kinetic description to macroscopic transport theory. The central claim is that the classical Boltzmann equation, though enormously successful, inherits a physically inadequate microscopic ontology from the hard-sphere model. In the framework adopted here, each particle is modeled instead as a finite Hopf-type topological object with internal labels, finite spatial support, and retarded substrate response. Interparticle interaction is therefore not reduced to instantaneous geometric impact, but arises through overlap of effective core regions together with delayed substrate-mediated feedback. Starting from the Liouville equation for the full many-body distribution, we construct a BBGKY hierarchy appropriate to this ontology, introduce a memory-corrected molecular-chaos closure, and derive a corrected kinetic description whose collision sector is dynamically renormalized by nonlocal and history-dependent contributions. We then show that the first-order memory sector of this corrected kinetic theory induces a retained microscopic closure that yields, in the appropriate macroscopic limit, memory-extended constitutive laws of the kind developed in earlier papers of the series, including a modified Navier–Stokes equation with memory stress, a corrected Fourier law, and a corrected Fick law. The result is not claimed to be the final quantitatively completed transport theory for all materials. Its purpose is narrower and more structural: to provide statistical mechanics with a microphysical basis consistent with global realism, to expose the ontological limitations of the hard-sphere picture, and to show that retarded substrate response enters transport theory as a controlled consequence of a different particle ontology rather than as an ad hoc macroscopic addition. By establishing a logically closed derivational chain from the microscopic ontology of topological excitations to the macroscopic memory-extended constitutive laws, the present manuscript provides the essential microscopic-to-macroscopic bridge that completes the foundational architecture of the global realism program.
Jianming Wang (Tue,) studied this question.
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